Transmission device, transmission method, reception device, and reception method

ABSTRACT

An image data of pictures constituting moving image data is encoded to generate an encoded video stream. In this case, the image data of the pictures constituting the moving image data is classified into a plurality of levels and encoded to generate a video stream having the image data of the pictures at the respective levels. Hierarchical composition is equalized between a low-level side and a high-level side, and corresponding pictures on the low-level side and the high-level side are combined into one set and are sequentially encoded. This allows a reception side to decode the encoded image data of the pictures on the low-level side and the high-level side with a smaller buffer size and a reduced decoding delay.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.17/163,964, filed Feb. 1, 2021, which is a continuation of U.S.application Ser. No. 16/549,024, filed Aug. 23, 2019 (now U.S. Pat. No.11,122,280), which is a continuation of U.S. application Ser. No.15/119,582, filed Aug. 17, 2016 (now U.S. Pat. No. 10,455,243), theentire contents of each of which are incorporated herein by reference.U.S. application Ser. No. 15/119,582 is a National Stage ofPCT/JP2015/054090, filed Feb. 16, 2015, and claims the benefit ofpriority from Japanese Application No. 2014-045763, filed Mar. 7, 2014.

TECHNICAL FIELD

The present invention relates to a transmission device, a transmissionmethod, a reception device, and a reception method, more specifically,to a transmission device that subjects image data of picturesconstituting moving image data to hierarchical encoding and transmitsthe same, and others.

BACKGROUND ART

To service compressed moving images by way of broadcasting, networks, orthe like, there is an upper limit on replayable frame frequencydepending on decoding capability of a receiver. Therefore, serviceproviders need to limit their services to low-frame frequency servicesor provide concurrently high-frame frequency services and low-framefrequency services, with consideration given to replaying capabilitiesof the prevailing receivers.

To correspond to high-frame frequency services, the receivers becomehigher in cost, which is a disincentive to popularization. Wheninexpensive receivers dedicated to low-frame frequency services areinitially in widespread use and service providers start high-framefrequency services in the future, customers cannot receive thehigh-frame frequency services without new receivers, which is adisincentive to proliferation of the new services.

For example, there is proposed time-direction scalability by subjectingimage data of pictures constituting moving image data to hierarchicalencoding by high efficiency video coding (HEVC) (refer to Non-patentDocument 1). At the reception side, the levels of the pictures can beidentified based on temporal ID (temporal_id) information inserted inthe header of a network abstraction layer (NAL) unit, which allowsselective decoding up to the level corresponding to decoding capability.

CITATION LIST Non-Patent Document

-   Non-patent Document 1: Gary J. Sullivan, Jens-Rainer Ohm, Woo-Jin    Han, Thomas Wiegand, “Overview of the High Efficiency Video Coding    (HEVC) Standard” IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS FOR VIDEO    TECNOROGY, VOL. 22, NO. 12, pp. 1649-1668, DECEMBER 2012

SUMMARY OF THE INVENTION Problems to be Solved by the Invention

An object of the subject technique is to allow favorable decoding at thereception side.

Solutions to Problems

A concept of the subject technique lies in a transmission deviceincluding:

an image encoding unit that classifies image data of picturesconstituting moving image data into a plurality of levels and encodesthe classified image data of the pictures at the respective levels togenerate a video stream having the encoded image data of the pictures atthe respective levels; and

a transmission unit that transmits a container in a predetermined formatcontaining the generated video stream, wherein

the image encoding unit equalizes hierarchical composition between alow-level side and a high-level side, and combines correspondingpictures on the low-level side and the high-level side into one set andencodes the same sequentially.

According to the subject technique, the image encoding unit encodes theimage data of the pictures constituting the moving image data togenerate the video stream (encoded stream). In this case, the image dataof the pictures constituting the moving image data is classified into aplurality of levels and encoded to generate the video stream having theimage data of the pictures at the respective levels. The hierarchicalcomposition is equalized between the low-level side and the high-levelside. Corresponding pictures on the low-level side and the high-levelside are combined into one set and are sequentially encoded.

The transmission unit transmits the container in the predeterminedformat including the foregoing video stream. For example, the imageencoding unit may generate a single video stream having the encodedimage data of the pictures at the respective levels or divide theplurality of levels into two sets of the upper-level side and thelower-level side and generate two video streams having the encoded imagedata of the pictures in the respective level sets.

According to the subject technique, the hierarchical composition isequalized between the low-level side and the high-level side, andcorresponding pictures on the low-level side and the high-level side arecombined into one set and are sequentially encoded. This allows thereception side to decode the encoded image data of the pictures on thelow-level side and the high-level side with a smaller buffer size and areduced decoding delay.

In the subject technique, for example, a hierarchical informationinsertion unit that inserts hierarchical information into a layer of thecontainer may further be included. In this case, for example, thehierarchical information may have information on level specified valuesfor the respective levels. In addition, in this case, for example, thehierarchical information insertion unit may insert the hierarchicalinformation into the layer of the container at positions insynchronization with the encoded image data of the pictures in the videostream.

For example, the hierarchical information insertion unit may insert thehierarchical information into an extension field of a PES packet. Inthis case, the hierarchical information insertion unit may insert thehierarchical information into the extension field of the PES packet atleast for each coded video sequence. In addition, in this case, forexample, an information insertion unit that inserts information fordescribing explicitly whether the hierarchical information is insertedinto the extension field of the PES packet may further be included undera program map table.

In addition, for example, the hierarchical information insertion unitmay insert the hierarchical information under a program map table. Inaddition, for example, the hierarchical information insertion unit mayinsert the hierarchical information under an event information table.

The hierarchy information is inserted in the layer of the container, andthe reception side can refer to the hierarchy information to retrieveselectively from the video stream the encoded image data of the picturesup to the level commensurate with the capability of the decoder in aneasy manner.

In addition, another concept of the subject technique lies in areception device including a reception unit that receives a container ina predetermined format that contains a video stream having encoded imagedata of pictures obtained by classifying image data of the picturesconstituting moving image data into a plurality of levels and encodingthe same, wherein

in the encoding, hierarchical composition is equalized between alow-level side and a high-level side, and corresponding pictures on thelow-level side and the high-level side are combined into one set and aresequentially encoded, and

the reception device further includes a processing unit that processesthe received container.

According to the subject technique, the reception unit receives thecontainer in the predetermined format. The container contains the videostream having image data of the pictures at the respective levelsobtained by classifying the image data of the pictures constituting themoving image data into a plurality of levels and encoding the same. Inthis case, in the process of encoding, the hierarchical composition isequalized between the low-level side and the high-level side, andcorresponding pictures on the low-level side and the high-level side arecombined into one set and are sequentially encoded.

The processing unit processes the received container. For example, theprocessing unit may be configured to retrieve selectively the encodedimage data of the pictures at a predetermined level and lower ones fromthe video stream and decode the same based on the hierarchy information,thereby obtaining the image data of the pictures at the predeterminedlevel and lower ones.

As described above, according to the subject technique, in the videostream contained in the received container, the hierarchical compositionis equalized between the low-level side and the high-level side, andcorresponding pictures on the low-level side and the high-level side arecombined into one set and are sequentially encoded. This makes itpossible to decode the encoded image data of the pictures on thelow-level side and the high-level side with a smaller buffer size and areduced decoding delay.

According to the subject technique, hierarchical information may beinserted into a layer of the container, and

the processing unit may retrieve selectively from the video stream theencoded image data of the pictures at a predetermined level and lowerones and decode the same, based on the hierarchical information, toobtain the image data of the pictures at the predetermined level andlower ones. In this case, it is easy to retrieve selectively from thevideo stream the encoded image data of the pictures at the levelcommensurate with the capability of the decoder in an easy manner.

Effects of the Invention

According to the subject technique, the reception side can performfavorable decoding. The advantages of the technique are not limited tothe ones described here but may be any of advantages described in thesubject disclosure.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram of a transmission/reception system as anembodiment.

FIG. 2 is a block diagram of a configuration example of a transmissiondevice.

FIG. 3 is a diagram illustrating an example of hierarchical encodingperformed by an encoder.

FIGS. 4A and 4B are diagrams illustrating a structural example (Syntax)of an NAL unit header and the contents (Semantics) of major parametersin the structural example.

FIG. 5 is a diagram illustrating another example of hierarchicalencoding performed by the encoder.

FIG. 6 is a diagram illustrating a configuration example of encodedimage data of pictures.

FIGS. 7A and 7B are diagrams illustrating a structural example (Syntax)of a layer decoding descriptor (Layer_decoding_descriptor).

FIG. 8 is a diagram illustrating the contents (Semantics) of majorinformation in the structural example of the layer decoding descriptor.

FIG. 9 is a diagram illustrating a structural example (Syntax) of a PESextension field data “pes_extension_field_data( )”.

FIGS. 10A and 10B are diagrams illustrating a structural example(Syntax) of a PES extension descriptor (PES_extension_descriptor) andthe contents (Semantics) of major information in the structural example.

FIG. 11 is a diagram of a configuration example of a transport stream TSin the case where single-stream distribution is performed andhierarchical information is inserted under a program map table.

FIG. 12 is a diagram of a configuration example of the transport streamTS in the case where two-stream distribution is performed andhierarchical information is inserted under the program map table.

FIG. 13 is a diagram of a configuration example of the transport streamTS in the case where single-stream distribution is performed andhierarchical information is inserted under an event information table.

FIG. 14 is a diagram of a configuration example of the transport streamTS in the case where two-stream distribution is performed andhierarchical information is inserted under the event information table.

FIG. 15 is a diagram of a configuration example of the transport streamTS in the case where single-stream distribution is performed andhierarchical information is inserted into an extension field of a PESpacket header.

FIG. 16 is a diagram of a configuration example of the transport streamTS in the case where two-stream distribution is performed andhierarchical information is inserted into the extension field of the PESpacket header.

FIG. 17 is a block diagram illustrating a configuration example of areception device.

FIG. 18 is a diagram illustrating an example of correspondence betweensignaling of “level_idc” and hierarchical information of coded imagedata with changes in hierarchical composition.

MODE FOR CARRYING OUT THE INVENTION

An embodiment for carrying out the invention (hereinafter, referred toas “embodiment”) will be described below. The descriptions will be givenin the following order:

1. Embodiment

2. Modification example

1. Embodiment

[Transmission/Reception System]

FIG. 1 illustrates a configuration example of a transmission/receptionsystem 10 as an embodiment. The transmission/reception system 10 has atransmission device 100 and a reception device 200.

The transmission device 100 transmits a transport stream TS as acontainer carried on broadcast waves or in packets over a network. Thetransport stream TS contains a video stream in which image data ofpictures constituting moving image data is classified into a pluralityof levels and encoded data of the image data of the pictures at therespective levels is included. In this case, the transport stream TScontains a single video stream having the encoded image data of thepictures at the respective levels or two video streams in which theplurality of levels is divided into two sets of high-level side andlow-level side and the encoded image data of the pictures at therespective level sets is included.

For example, the referenced pictures are encoded according to H.264/AVCor H.265/HEVC such that they belong to their levels and/or lower ones.In this case, the hierarchical composition is equalized between thelow-level side and the high-level side, and corresponding pictures onthe low-level side and the high-level side are combined into one set andare sequentially encoded. Performing such encoding allows the receptionside to decode the encoded image data of the pictures on the low-levelside and the high-level side with a smaller buffer size and a reduceddecoding delay.

Level identification information is added to the encoded image data ofthe pictures at the respective levels to identify the levels to whichthe pictures belong. In the embodiment, the level identificationinformation (“nuh_temporal_id_plus1” indicative of temporal_id) is addedto the headers of the NAL units (nal_unit) of the pictures. Adding thelevel identification information allows the reception side to retrieveselectively the encoded image data at the predetermined level and lowerones for decode processing.

Hierarchical information including information on level specified valuesat the respective levels and others is inserted into the layer of thecontainer. The reception side can refer to the hierarchical informationto retrieve selectively from the video stream the encoded image data ofthe pictures at the level commensurate with the capability of thedecoder in an easy manner. For example, the hierarchical information isinserted under a program map table (PMT) or under an event informationtable (EIT).

In addition, the hierarchical information is inserted into PES extensionfields of the headers of PES packets at positions in synchronizationwith the encoded image data of the pictures in the video stream, forexample. This allows the reception side to, even with changes in thehierarchical composition, retrieve selectively from the video stream theencoded image data of the pictures at the level commensurate with thecapability of the decoder.

When the hierarchical information is inserted into the extension fieldof the PES packet as described above, identification informationindicating that the hierarchical information is inserted into theextension field of the PES packet is inserted under the program maptable. In this case, the reception side can identify a situation thatthe hierarchical information is inserted into the extension field of thePES packet based on the identification information.

The reception device 200 receives the transport stream TS sent from thetransmission device 100 on broadcast waves or in packets over a network.The reception device 200 processes the transport stream TS. In thiscase, the reception device 200 retrieves selectively from the videostream the encoded image data of the pictures at a predetermined leveland lower ones commensurate with the capability of the decoder anddecodes the same based on the hierarchy information contained in thelayer of the container, thereby obtaining the image data of the picturesat the predetermined level and lower ones.

“Configuration of the Transmission Device”

FIG. 2 illustrates a configuration example of the transmission device100. The transmission device 100 has a central processing unit (CPU)101, an encoder 102, a compressed data buffer (cpb: coded picturebuffer) 103, a multiplexer 104, and a transmission unit 105. The CPU 101is a control unit that controls the operations of the components of thetransmission device 100.

The encoder 102 inputs uncompressed moving image data VD to performhierarchical encoding. The encoder 102 classifies the image data ofpictures constituting the moving image data VD into a plurality oflevels. Then, the encoder 102 encodes the classified image data of thepictures at the respective levels to generate a video stream having theencoded image data of the pictures at the respective levels.

The encoder 102 performs encoding such as H.264/AVC or H.265/HEVC. Atthat time, the encoder 102 performs encoding such that the referencedpictures belong to their levels and/or lower ones. The encoder 102 alsodivides the plurality of levels into low-level side and high-level side,and equalizes the hierarchical composition between the low-level sideand the high-level side, and combines corresponding pictures on thelow-level side and the high-level side into one set and encodes the samesequentially.

FIG. 3 illustrates an example of hierarchical encoding performed by theencoder 102. In this example, the image data of the pictures isclassified into six levels of 0 to 5, and is subjected to encoding.

The vertical axis indicates the levels. The values 0 to 5 are set as thetemporal_id (level identification information) added to the headers ofthe NAL units (nal_unit) constituting the encoded image data of thepictures at the levels 0 to 5. Meanwhile, the horizontal axis indicatesthe picture order of composition (POC), the display time is earlier withincreasing proximity to the left side and is later with increasingproximity to the right side.

FIG. 4A illustrates a structural example (Syntax) of the NAL unitheader, and FIG. 4B illustrates the contents (Semantics) of majorparameters in the structural example. The 1-bit field“Forbidden_zero_bit” is essentially 0. The 6-bit field “Nal_unit_type”indicates the NAL unit type. The 6-bit field “Nuh_layer_id” is 0 as aprecondition. The 3-bit field “Nuh_temporal_id_plus1” indicatestemporal_id and takes the value increased by one (1 to 6).

Returning to FIG. 3 , rectangular frames indicate pictures, and numbersin the rectangular frames indicate the order of coded pictures, that is,the encoding order (the decoding order at the reception side). Forexample, eight pictures of “0” to “7” constitute a sub group ofpictures, and the picture “0” becomes the first picture in the sub groupof pictures. Several sub groups of pictures are collected into a groupof pictures (GOP).

In this example, three levels of 0 to 2 are on the low-level side andthree levels of 3 to 5 are on the high-level side. As illustrated in thedrawing, the hierarchical composition is equalized between the low-levelside and the high-level side, and corresponding pictures on thelow-level side and the high-level side are combined into one set and aresequentially encoded. For example, the picture “0” on the low-level sideand the picture “1” on the high-level side are first combined into oneset and subjected to encoding, and then the picture “2” on the low-levelside and the picture “3” on the high-level side are combined into oneset and subjected to encoding. The pictures at the following levels areencoded in the same manner. In this case, the low levels are limited tolevels lower than a specific level. Accordingly, to decode the picturesat the low levels, only the pictures at the limited low levels can bedecoded and displayed in a stable manner. This matter also applies evenwhen the pictures are not divided into the low levels and the highlevels.

Returning to FIG. 3 , solid-line and broken-line arrows indicate thereference relationships between the pictures in encoding. For example,the picture “0” is an intra picture (I picture) that needs no referenceto other pictures, and the picture “1” is a P picture that is encodedwith reference to the “1” picture. The picture “2” is a B picture thatis encoded with reference to the “0” picture and a picture in theprevious sub group of pictures (not illustrated). The picture “3” is a Bpicture that is encoded with reference to the “0” and “2” pictures.Similarly, the other pictures are encoded with reference to picturesclose to them in the picture order of composition. The code “D”indicates how much each picture is distant from the referenced picturein the picture order of composition. Without the indication of “D,” D=1.

FIG. 5 illustrates another example of hierarchical encoding performed bythe encoder 102. Although no detailed description will be provided, inthe example of FIG. 3 , the picture order of composition on thehigh-level side is one picture behind the picture order of compositionon the low-level side, whereas, in the example of FIG. 5 , the pictureorder of composition on the high-level side is one picture ahead of thepicture order of composition on the low-level side. In this case, thehierarchical composition is equalized between the low-level side and thehigh-level side, and corresponding pictures on the low-level side andthe high-level side are combined into one set and are sequentiallyencoded.

The encoder 102 generates a video stream having the encoded image dataof the pictures at the respective levels. For example, the encoder 102generates a single video stream having the encoded image data of thepictures at the respective levels or generates two video streams havingthe encoded image data of the pictures on the upper-order level side andthe lower-order level side.

FIG. 6 illustrates a configuration example of encoded image data of thepictures. The encoded image data of the first picture of the GOP iscomposed of NAL units of access unit delimiter (AUD), video parameterset (VPS), sequence parameter set (SPS), picture parameter set (PPS),picture supplemental enhancement information (PSEI), SLICE, slicesupplemental enhancement information (SSEI), and end of sequence (EOS).Meanwhile, the pictures other than the first picture of the GOP arecomposed of NAL units of AUD, PPS, PSEI, SLICE, SSEI, and EOS. The unitVPS can be transmitted together with the unit SPS once per sequence(GOP), and the unit PPS can be transmitted for each picture. The unitEOS may not exist.

The bit stream level specified value “general_level_idc” is insertedinto the sequence parameter set (SPS). In addition, when the picturesbelonging to the levels indicated by “temporal_id” are bound into sublayers (sub_layer) and “Sublayer_level_presented_flag” is set to “1,”the bit rate level specified value for each sub layer“sublayer_level_idc” can also be inserted into the SPS. This matter isapplied to not only the SPS but also the VPS.

For example, the example of hierarchical encoding illustrated in FIG. 3will be discussed. The value of “general_level_idc” inserted into theSPS is a level value including all the pictures at the levels 0 to 5.For example, when the frame rate is 120 P, the value is “Level 5.2.” Thevalue of “sublayer_level_idc[2]” inserted into the SPS becomes a levelvalue including only the pictures at the levels 0 to 2. For example,when the frame rate is 60 P, the value is “Level 5.1.”

Returning to FIG. 2 , the compressed data buffer (cpb) 103 accumulatestemporarily the video stream containing the encoded image data of thepictures at the respective levels generated by the encoder 102. Themultiplexer 104 reads the video stream accumulated in the compresseddata buffer 103, turns the same into a PES packet, and further turns thesame into a transport packet to multiplex the same, thereby obtaining atransport stream TS as a multiplexed stream. The transport stream TScontains one or more video streams as described above.

The multiplexer 104 inserts the hierarchical information into the layerof the container. The transmission unit 105 transmits the transportstream TS obtained by the multiplexer 104 on broadcast waves or inpackets over a network to the reception device 200.

[Insertion of the hierarchical information]

The insertion of the hierarchical information by the multiplexer 104will be further explained. The multiplexer 104 inserts the hierarchicalinformation to the layer of the container by any of the followingmethods (A), (B), and (C), for example:

(A) Insert the hierarchical information under the program map table(PMT);

(B) Insert the hierarchical information under the event informationtable (EIT); and

(C) Insert the hierarchical information into the extension field of theheader of the PES packet.

“Description of (A)”

The transport stream TS contains a PMT as program specific information(PSI). The PMT has a video elementary loop (video ES1 loop) withinformation related to each video stream. In the video elementary loop,information such as stream type and packet identifier (PID) is arrangedand descriptors describing information related to each video stream arealso arranged in correspondence with the video stream.

The multiplexer 104 inserts a layer decoding descriptor(Layer_decoding_descriptor) newly defined as one of the descriptors.FIGS. 7A and 7B illustrate a structural example (Syntax) of the layerdecoding descriptor. FIG. 8 illustrates the contents (Semantics) ofmajor information in the structural example.

The 8-bit field “Layer_decoding_descriptor_tag” indicates descriptortype, and in this example, layer decoding descriptor. The 8-bit field“Layer_decoding_descriptor_length” indicates the length (size) of thedescriptor as the number of bytes of the subsequent “layer_information().”

FIG. 7B illustrates a structural example (Syntax) of “layer_information().” The 3-bit field “layer_minimum LMI” indicates the level (layer)indicated by the minimum value of “temporal_id.” The 3-bit field“layer_maximum LMX” indicates the level (layer) indicated by the maximumvalue of “temporal_id.” In this example, the number of layers to which“temporal_id” is assigned is (LMX−LMI+1). The 8-bit field“layer_level_idc[i]” indicates “level_idc” as level specified value ofthe bit rate at each level.

“Description of (B)”

The transport stream TS also contains EIT as SI (serviced information)for management of each event. The multiplexer 104 arranges the layerdecoding descriptor described above (see FIGS. 7A and 7B) under the EIT.In this case, the multiplexer 104 also arranges a conventionally knowncomponent descriptor under the EIT to make a link with the PES stream.

“Description of (C)”

PES extension field can be provided in the header of the PES packet. Themultiplexer 104 inserts PES extension field data having hierarchicalinformation into the extension field. In this manner, the multiplexer104 provides the PES extension field in the header of the PES packet toinsert the PES extension field data having hierarchical information atleast for each coded video sequence (CVS), for example. FIG. 9illustrates a structural example (Syntax) of the PES extension fielddata “pes_extension_field_data( ).”

The “PES_extension field length” is given outside the syntax structure.The 8-bit field “start sync byte” indicates the code value representingthe start of the extension field. The 8-bit field “extension_field_type”indicates the type of the extension field, which means the supply ofhierarchical information in this example. The “layer_information( )” hasfields “layer_minimum LMI,” “layer_minimum LMX,” and“layer_level_idc[i],” as described above (see FIG. 7B).

In this case, the multiplexer 104 arranges a PES extension descriptor(PES_extension_descriptor) as one of the descriptors in the videoelementary loop to describe explicitly that the hierarchical informationis inserted into the PES extension field.

FIG. 10A illustrates a structural example (Syntax) of thePES_extension_descriptor (PES_extension_descriptor). FIG. 10Billustrates the contents (Semantics) of major information in thestructural example. The 8-bit field “PES_extention_descriptor_tag”indicates the type of the descriptor, which means thePES_extension_descriptor in this example.

The 8-bit field “PES_extention_descriptor_length” indicates the length(size) of the descriptor as the number of subsequent bytes. The 1-bitfield “PES extension existed” indicates whether the PES extension fieldof the applicable PES stream is encoded. The value “1” indicates thatthe PES extension field is encoded, and the value “0” indicates that thePES extension field is not encoded.

[Configuration of the Transport Stream TS]

FIG. 11 illustrates a configuration example of the transport stream TSin the case where single-stream distribution is performed and thehierarchical information is inserted under the program map table (PMT)(the foregoing case (A)). In this configuration example, there is a PESpacket “video PES1” of a video stream having image data encoded by HEVCof pictures at a plurality of levels, for example.

The encoded image data of the pictures have NAL units such as VPS, SPS,PPS, SLICE, and SEI. As described above, the level identificationinformation (“nuh_temporal_id_plus1” indicative of temporal_id) for thepicture is arranged in the headers of the NAL units. The level specifiedvalue of the bit stream “general_level_idc” is inserted into the SPS. Inaddition, the pictures belonging to the levels indicated by“temporal_id” are bound into sub layers (sub_layer) and“Sublayer_level_presented_flag” is set to “1,” whereby the bit ratelevel specified value for each sub layer “sublayer_level_idc” isinserted into the SPS.

The transport stream TS also contains the program map table (PMT) asprogram specific information (PSI). The PSI is information describing towhich program each elementary stream contained in the transport streambelongs.

The PMT has a program loop describing information related to the entireprogram. The PMT also has an elementary loop with information related toeach elementary stream. In this configuration example, there exists avideo elementary loop (video ES loop).

In the video elementary loop, information such as stream type and packetidentifier (PID) is arranged in correspondence with the video stream(video PES1), and descriptors describing information related to thevideo stream are also arranged. As one of the descriptors, the layerdecoding descriptor (Layer_decoding_descriptor) described above isinserted.

For example, in the examples of hierarchical encoding illustrated inFIGS. 3 and 5 , the contents described by the descriptor are as follows:“layer_minimum LMI”=0, “layer_maximum LMX”=5, “layer_level_idc[0]”=Level5, “layer_level_idc[1]”=Level 5, “layer_level_idc[2]”=Level 5.1,“layer_level_idc[3]”=Level 5.2, “layer_level_idc[4]”=Level 5.2, and“layer_level_idc[5]”=Level 5.2.

FIG. 12 illustrates a configuration example of the transport stream TSin the case where two-stream distribution is performed and thehierarchical information is inserted under the program map table (PMT)(the foregoing case (A)). In this configuration example, a plurality oflevels is divided into two sets of low-level side and high-level side,and there exist PES packets “video PES1” and “video PES2” of the videostreams having image data encoded by HEVC of the pictures of the twosets, for example.

The encoded image data of the pictures on the low-level side have NALunits such as VPS, SPS, PPS, SLICE, and SEI. The hierarchicalidentification information (“nuh_temporal_id_plus1” indicative oftemporal_id) of the picture is arranged in the header of the NAL units.The level specified value of the bit stream “general_level_idc” isinserted into the SPS. In addition, the pictures belonging to the levelsindicated by “temporal_id” are bound into sub layers (sub_layer) and“sublayer_level_presented_flag” is set to “1,” whereby the bit ratelevel specified value for each sub layer “sublayer_level_idc” isinserted into the SPS.

Meanwhile, the encoded image data of the pictures on the high-level sidehave NAL units such as PPS and SLICE. The hierarchical identificationinformation (“nuh_temporal_id_plus1” indicative of temporal_id) of thepicture is arranged in the headers of the NAL units.

The transport stream TS also contains the program map table (PMT) asprogram specific information (PSI). The PSI is information describing towhich program each elementary stream contained in the transport streambelongs.

The PMT has a program loop describing information related to the entireprogram. The PMT also has an elementary loop with information related toeach elementary stream. In this configuration example, there exist twovideo elementary loops (video ES1 loop and video ES2 loop).

In the video elementary loop, information such as stream type and packetidentifier (PID) is arranged in correspondence with the video streams(video PES1 and video PES2), and descriptors describing informationrelated to the video streams are also arranged. As one of thedescriptors, the layer decoding descriptor (Layer_decoding_descriptor)described above is inserted.

For example, in the examples of hierarchical encoding illustrated inFIGS. 3 and 5 , the contents described by the descriptors correspondingto the PES packets “video PES1” and “video PES2” are as follows: thedescriptor corresponding to the PES packet “video PES1” describes “layerminimum LMI”=0, “layer_maximum LMX”=2, “layer_level_idc[0]”=Level 5,“layer_level_idc[1]”=Level 5, and “layer_level_idc[2]”=Level 5.1; andthe descriptor corresponding to the PES packet “video PES1” describes“layer minimum LMI”=3, “layer maximum LMX”=5, “layer_level_idc[3]”=Level5.2, “layer_level_idc[4]”=Level 5.2, and “layer_level_idc[5]”=Level 5.2.

FIG. 13 illustrates a configuration example of the transport stream TSin the case where single-stream distribution is performed and thehierarchical information is inserted under the event information table(EIT) (the foregoing case (B)). In this configuration example, as in theconfiguration example of FIG. 11 , there exists the PES packet “videoPES1” of the video stream having the image data encoded by HEVC of thepictures at a plurality of levels, for example.

The transport stream TS contains the program map table (PMT) as programspecific information (PSI). The PSI is information describing to whichprogram each elementary stream contained in the transport streambelongs.

The PMT has a program loop describing information related to the entireprogram. The PMT also has elementary loops with information related toeach elementary stream. The PMT has a program loop describinginformation related to the entire program. The PMT also has anelementary loop with information related to each elementary stream. Inthis configuration example, there exists a video elementary loop (videoES loop). In the video elementary loop, information such as stream typeand packet identifier (PID) is arranged in correspondence with the videostream (video PES1), and descriptors describing information related tothe video stream are also arranged.

The transport stream TS also contains EIT as SI (serviced information)for management of each event. The layer decoding descriptor(Layer_decoding_descriptor) described above is arranged under the EIT.Although not explained in detail, the contents described by thedescriptor are the same as those in the configuration example of FIG. 11. A conventionally known component descriptor is arranged under the EITto make a link with the PES packet “video PES1.”

FIG. 14 illustrates a configuration example of the transport stream TSin the case where two-stream distribution is performed and thehierarchical information is inserted under the event information table(EIT) (the foregoing case (B)). In this configuration example, aplurality of levels is divided into two sets of low-level side andhigh-level side, and there exist PES packets “video PES1” and “videoPES2” of the video streams having image data encoded by HEVC of thepictures of the two sets, for example, as in the configuration exampleof FIG. 12 .

The transport stream TS also contains the program map table (PMT) asprogram specific information (PSI). The PSI is information describing towhich program each elementary stream contained in the transport streambelongs.

The PMT has a program loop describing information related to the entireprogram. The PMT also has an elementary loop with information related toeach elementary stream. In this configuration example, there exist twovideo elementary loops (video ES1 loop and video ES2 loop). In the videoelementary loop, information such as stream type and packet identifier(PID) is arranged in correspondence with the video streams (video PES1and video PES2), and descriptors describing information related to thevideo streams are also arranged.

The transport stream TS also contains EIT as serviced information (SI)for management of each event. The layer decoding descriptors(Layer_decoding_descriptor) corresponding to the PES packets “videoPES1” and “video PES2” are arranged under the EIT. Although notexplained in detail, the contents described by the descriptors are thesame as those in the configuration example of FIG. 12 . A conventionallyknown component descriptor is arranged under the EIT to make links withthe PES packets “video PES1” and “video PES2.”

FIG. 15 illustrates a configuration example of the transport stream TSin the case where single-stream distribution is performed and thehierarchical information is inserted into the extension field of theheader of the PES packet (the foregoing case (C)). In this configurationexample, there is a PES packet “video PES1” of a video stream havingimage data encoded by HEVC of pictures at a plurality of levels, forexample, as in the configuration example of FIG. 11 .

A PES extension field is provided in the header of the PES packet, andPES extension field data “pes_extension_field_data( )” having“layer_information( )” is inserted into the PES extension field.Although not described in detail, the contents described in “layerinformation( )” are the same as those described by the layer decodingdescriptor in the configuration example of FIG. 11 .

The transport stream TS also contains the program map table (PMT) asprogram specific information (PSI). The PSI is information describing towhich program each elementary stream contained in the transport streambelongs.

The PMT has a program loop describing information related to the entireprogram. The PMT also has an elementary loop with information related toeach elementary stream. In this configuration example, there exists avideo elementary loop (video ES loop).

In the video elementary loop, information such as stream type and packetidentifier (PID) is arranged in correspondence with the video streams(video PES1 and video PES2), and descriptors describing informationrelated to the video streams are also arranged. As one of thedescriptors, a PES extention descriptor (PES extention descriptor) isinserted. The PES extention descriptor is a descriptor to describeexplicitly that the hierarchical information is inserted into the PESextension field.

FIG. 16 illustrates a configuration example of the transport stream TSin the case where two-stream distribution is performed and thehierarchical information is inserted into the extension field of theheader of the PES packet (the foregoing case (C)). In this configurationexample, a plurality of levels is divided into two sets of low-levelside and high-level side, and there exist PES packets “video PES1” and“video PES2” of the video streams having image data encoded by HEVC ofthe pictures of the two sets, for example, as in the configurationexample of FIG. 12 .

A PES extension field is provided in the header of the PES packet “videoPES1”, and PES extension field data “pes_extension_field_data( )” having“layer_information( )” is inserted into the PES extension field.Although not described in detail, the contents described in “layerinformation( )” are the same as those described by the layer decodingdescriptor corresponding to the PES packet “video PES1” in theconfiguration example of FIG. 12 .

A PES extension field is provided in the header of the PES packet “videoPES2”, and PES extension field data “pes_extension_field_data( )” having“layer_information( )” is inserted into the PES extension field.Although not described in detail, the contents described in“layer_information( )” are the same as those described by the layerdecoding descriptor corresponding to the PES packet “video PES2” in theconfiguration example of FIG. 12 .

The transport stream TS also contains the PMT (program map table) as PSI(program specific information). The PSI is information describing towhich program each elementary stream contained in the transport streambelongs.

The PMT has a program loop describing information related to the entireprogram. The PMT also has an elementary loop with information related toeach elementary stream. In this configuration example, there exist twovideo elementary loops (video ES1 loop and video ES2 loop).

In the video elementary loop, information such as stream type and packetidentifier (PID) is arranged in correspondence with the video streams(video PES1 and video PES2), and descriptors describing informationrelated to the video streams are also arranged. As one of thedescriptors, a PES extention descriptor (PES_extention_descriptor) isinserted.

The PES extention descriptor is a descriptor to describe explicitly thatthe hierarchical information is inserted into the PES extension field.

Operation of the transmission device 100 illustrated in FIG. 2 will bebriefly described. Uncompressed moving image data VD is input into theencoder 102. The encoder 102 subjects the moving image data VD tohierarchical encoding. Specifically, the encoder 102 classifies imagedata of pictures constituting the moving image data VD into a pluralityof levels and encodes the same, thereby generating a video stream havingencoded image data of the pictures at the respective levels.

In this case, the referenced pictures are encoded such that they belongto their levels and/or lower ones. In this case, a plurality of levelsis divided into two of low-level side and high-level side, and thehierarchical composition is equalized between the low-level side and thehigh-level side, and corresponding pictures on the low-level side andthe high-level side are combined into one set and are sequentiallyencoded. Also in this case, a single video stream having the encodedimage data of the pictures at the respective levels is generated, or twovideo streams having the encoded image data of the pictures on theupper-order level side and the lower-order level side are generated.

The video stream generated by the encoder 102 and containing the encodeddata of pictures at the respective levels is supplied to the compresseddata buffer (cpb) 103 and is temporarily accumulated there. Themultiplexer 104 reads the video stream from the compressed data buffer103, turns the same into PES packet, further turns the same intotransport packet for multiplexing, thereby obtaining the transportstream TS as a multiplexed stream. The transport stream TS contains oneor more video streams as described above.

When the multiplexer 104 generates the transport stream TS, thehierarchical information is inserted in the layer of the container underthe program map table (PMT), under the event information table (EIT), orin the extension field of the header of the PES packet. The transportstream TS generated by the multiplexer 104 is sent to the transmissionunit 105. The transmission unit 105 transmits the transport stream TS onbroadcast waves or in packets over a network to the reception device200.

“Configuration of the Reception Device”

FIG. 17 illustrates a configuration example of the reception device 200.The reception device 200 has a central processing unit (CPU) 201, areception unit 202, a demultiplexer 203, and a compressed data buffer(cpb: coded picture buffer) 204. The reception device 200 also has adecoder 205, a decompressed data buffer (dpb: decoded picture buffer)206, a post-processing unit 207, and a display unit 208. The CPU 201constitutes a control unit that controls operations of the components ofthe reception device 200.

The reception unit 202 receives the transport stream TS on broadcastwaves or in packets over a network transmitted from the transmissiondevice 100. The demultiplexer 203 retrieves selectively from thetransport stream TS the encoded image data of the pictures at the levelcommensurate with the capability of the decoder 205, and sends the sameto the compressed data buffer (cpb: coded picture buffer) 204. In thiscase, the demultiplexer 203 refers to the value of“nuh_temporal_id_plus1” indicative of “temporal_id” arranged in theheaders of the NAL units (nal_unit) of the pictures.

In this case, the demultiplexer 203 extracts the hierarchicalinformation inserted in the layer of the container, recognizes“layer_level_idc” at the respective levels from the hierarchicalinformation, and detects up to which level decoding is enabled accordingto the capability of the decoder 205. For example, in the examples ofhierarchical encoding of FIGS. 3 and 5 , it is assumed that“layer_level_idc[0]”=Level 5, “layer_level_idc[1]”=Level 5,“layer_level_idc[2]”=Level 5.1, “layer_level_idc[3]”=Level 5.2,“layer_level_idc[4]”=Level 5.2, and “layer_level_idc[5]”=Level 5.2. Inthis case, when the decoder 205 has a capability of 60 P, that is,“Level 5.1,” the demultiplexer 203 detects that decoding is enabled upto the level 2. In addition, in this case, when the decoder 205 has acapability of 120 P, that is, “Level 5.2,” the demultiplexer 203 detectsthat decoding is enabled up to the level 5.

The compressed data buffer (cpb) 204 accumulates temporarily the encodedimage data of pictures at the respective levels sent from thedemultiplexer 203. The decoder 205 reads and decodes the encoded imagedata of the pictures accumulated in the compressed data buffer 204 atdecode timings given by decoding time stamps (DTS) of the pictures, andsends the same to the decompressed data buffer (dpb) 206.

The decompressed data buffer (dpb) 206 accumulates temporarily the imagedata of the pictures decoded by the decoder 205. The post-processingunit 207 matches the frame rate for the image data of the pictures readsequentially at display timings given by presentation time stamps (PTS)from the decompressed data buffer (dpb) 206 with the display capability.

For example, when the frame rate of image data of the pictures afterdecoding is 60 fps and the display capability is 120 fps, thepost-processing unit 207 performs interpolation in the image data of thepictures after decoding such that the time-direction resolution becomesdoubled, and sends the same as image data of 120 fps to the display unit208.

The display unit 208 is composed of a liquid crystal display (LCD), anorganic electro-luminescence (EL) panel, or the like, for example. Thedisplay unit 208 may be an external device connected to the receptiondevice 200.

Operations of the reception device 200 illustrated in FIG. 17 will bedescribed briefly. The reception unit 202 receives the transport streamTS on broadcast waves or in packets over a network from the transmissiondevice 100. The transport stream TS is sent to the demultiplexer 203.The demultiplexer 203 retrieves selectively from the transport stream TSthe encoded image data of pictures at the level commensurate with thecapability of the decoder 205 based on the hierarchical informationinserted in the layer of the container, and sends the same to thecompressed data buffer (cpb) 204 for temporary accumulation.

The decoder 205 retrieves the encoded image data of pictures at therespective levels accumulated in the compressed data buffer 204. Thedecoder 205 then decodes the retrieved encoded image data of thepictures at the respective decode timings for the pictures, sends thesame to the decompressed data buffer (dpb) 206 for temporaryaccumulation.

Then, the image data of the pictures read sequentially at the displaytimings from the decompressed data buffer (dpb) 206 is sent to thepost-processing unit 207. The post-processing unit 207 subjects theimage data of the pictures to interpolation or sub sampling to match theframe rate with the display capability. The image data of the picturesprocessed by the post-processing unit 207 is supplied to the displayunit 208 for display of moving images.

As described above, in the transmission/reception system 10 illustratedin FIG. 1 , the transmission device 100 equalizes the hierarchicalcomposition between the low-level side and the high-level side, andcombines corresponding pictures on the low-level side and the high-levelside into one set and encodes the same sequentially. Accordingly, thereception device 200 can decode the encoded image data of the pictureson the low-level side and the high-level side at one collective timing,thereby reducing the buffer size and decreasing decode delay.

In addition, in the transmission/reception system 10 illustrated in FIG.1 , the transmission device 100 inserts the hierarchical informationinto the layer of the container to generate a transport streamcontaining a video stream having the image data of the encoded picturesat the respective levels. Accordingly, the reception device 200 canrefer to the hierarchical information to retrieve selectively from thevideo stream the encoded image data of the pictures up to the levelcommensurate with the capability of the decoder in an easy manner, forexample.

In the transmission/reception system 10 illustrated in FIG. 1 , thetransmission device 100 inserts the hierarchical information into thePES extension field of the header of the PES packet in the positionsynchronized with the encoded image data of the pictures of the videostream at least for each coded video sequence (CVS). This allows thereception side to, even with changes in the hierarchical composition,retrieve selectively from the video stream the encoded image data of thepictures up to the level commensurate with the capability of thedecoder.

FIG. 18 illustrates an example of correspondence between signaling of“level_idc” and hierarchical information of encoded image data withchanges in hierarchical composition. In this example, the hierarchicalcomposition changes from a first 50 P CVS system in which encoding isperformed at three levels of 0 to 2 to a second 50 P CVS system in whichencoding is performed at four levels of 0 to 3, and further changes to a100 P CVS system in which encoding is performed at six levels of 0 to 5.In the illustrated example, the hierarchical information is insertedunder the PMT. However, the foregoing matter also applies to the casewhere the hierarchical information is inserted under the EIT or into thePES extension field as described above.

In the period of the first 50 P CVS system, data is distributed in asingle video stream. The value of “general_level_idc” inserted into theSPS of the encoded image data is set to “Level 5.1” as a level valuecontaining all the pictures at the levels of 0 to 2. The value of“sublayer_level_idc[1]” as the level specified value of bit rate at thelevel of 1 is set to “Level 5.” In this case, the hierarchicalinformation is described as “layer_level_idc[0]” =Level 4.1,“layer_level_idc[1]”=Level 5, and “layer_level_idc[2]”=Level 5.1.”

In the period of the second 50 P CVS system, data is distributed in asingle video stream. The value of “general_level_idc” inserted into theSPS of the encoded image data is set to “Level 5.1” as a level valuecontaining all the pictures at the levels of 0 to 3. The value of“sublayer_level_idc[2]” as the level specified value of bit rate at thelevel of 2 is set to “Level 5.” In this case, the hierarchicalinformation is described as “layer_level_idc[0]” =Level 4,“layer_level_idc[1]”=Level 4.1, “layer_level_idc[2]”=Level 5”, and“layer_level_idc[3]”=Level 5.1.”

In the period of the 100 P CVS system, data is distributed in two videostreams. The value of “general_level_idc” inserted into the SPS of theencoded image data is set to “Level 5.2” as a level value containing allthe pictures at the levels of 0 to 5. The value of“sublayer_level_idc[2]” as the level specified value of bit rate at thelevel of 2 is set to “Level 5.1.” In this case, the hierarchicalinformation is described as “layer_level_idc[0]”=Level 4.1,“layer_level_idc[1]”=Level 5, “layer_level_idc[2]”=Level 5.1,“layer_level_idc[3]”=Level 5.2, “layer_level_idc[4]”=Level 5.2, and“layer_level_idc[5]”=Level 5.2.”

While the hierarchical composition changes as illustrated in thedrawing, if the decoder 205 of the reception device 200 corresponds to50 P, for example, the demultiplexer 203 retrieves the levels of 0 to 2in the period of the first 50 P CVS system, retrieves the levels of 0 to3 in the second 50 P CVS system, and retrieves the levels of 0 to 2 inthe period of the 100 P CVS system, based on the hierarchicalinformation, and sends the same to the compressed data buffer 204. Thedecoder 205 decodes the encoded image data of the pictures at theirrespective decode timings to obtain 50 P image data.

2. Modification Example

In the foregoing embodiment, the transmission/reception system 10 iscomposed of the transmission device 100 and the reception device 200.However, the configuration of the transmission/reception system to whichthe subject technique is applicable is not limited to this. For example,part of the reception device 200 may be formed as a set-top box and amonitor connected via a digital interface such as a high-definitionmultimedia interface (HDMI). The “HDMI” is a registered trademark.

In the foregoing embodiment, the container is a transport stream (MPEG-2TS). However, the subject technique is also applicable to other systemsin which data is distributed to reception terminals via a network suchas the Internet. In the Internet delivery, data is frequentlydistributed by a container in MP4 or other formats. That is, thecontainer may be a transport stream (MPEG-2 TS) employed under digitalbroadcasting standards, or any other container in various formats suchas MP4 used in the Internet delivery.

The subject technique may be configured as described below.

(1) A transmission device including:

an image encoding unit that classifies image data of picturesconstituting moving image data into a plurality of levels and encodesthe classified image data of the pictures at the respective levels togenerate a video stream having the encoded image data of the pictures atthe respective levels; and

a transmission unit that transmits a container in a predetermined formatcontaining the generated video stream, wherein

the image encoding unit equalizes hierarchical composition between alow-level side and a high-level side, and combines correspondingpictures on the low-level side and the high-level side into one set andencodes the same sequentially.

(2) The transmission device according to (1), further including

a hierarchical information insertion unit that inserts hierarchicalinformation into a layer of the container.

(3) The transmission device according to (2), wherein

the hierarchical information has information on level specified valuesfor the respective levels.

(4) The transmission device according to (2) or (3), wherein

the hierarchical information insertion unit inserts the hierarchicalinformation into the layer of the container at positions insynchronization with the encoded image data of the pictures in the videostream.

(5) The transmission device according to (4), wherein

the hierarchical information insertion unit inserts the hierarchicalinformation into an extension field of a PES packet.

(6) The transmission device according to (5), wherein

the hierarchical information insertion unit inserts the hierarchicalinformation into the extension field of the PES packet at least for eachcoded video sequence.

(7) The transmission device according to (5) or (6), further including

an information insertion unit that inserts information for describingexplicitly whether the hierarchical information is inserted into theextension field of the PES packet under a program map table.

(8) The transmission device according to (2) or (3), wherein

the hierarchical information insertion unit inserts the hierarchicalinformation under a program map table.

(9) The transmission device according to (2) or (3), wherein

the hierarchical information insertion unit inserts the hierarchicalinformation under an event information table.

(10) The transmission device according to any of (1) to (9), wherein

the image encoding unit generates a single video stream having theencoded image data of the pictures at the respective levels or dividesthe plurality of levels into two sets of the upper-level side and thelower-level side and generates two video streams having the encodedimage data of the pictures in the respective level sets.

(11) A transmission method including:

an image encoding step of classifying image data of picturesconstituting moving image data into a plurality of levels and encodingthe classified image data of the pictures at the respective levels togenerate a video stream having the encoded image data of the pictures atthe respective levels; and

a transmission step by a transmission unit of transmitting a containerin a predetermined format containing the generated video stream, wherein

at the image encoding step, hierarchical composition is equalizedbetween a low-level side and a high-level side, and correspondingpictures on the low-level side and the high-level side are combined intoone set and are sequentially encoded.

(12) A reception device including a reception unit that receives acontainer in a predetermined format that contains a video stream havingencoded image data of pictures obtained by classifying image data of thepictures constituting moving image data into a plurality of levels andencoding the same, whereinin the encoding, hierarchical composition is equalized between alow-level side and a high-level side, and corresponding pictures on thelow-level side and the high-levelside are combined into one set and are sequentially encoded, and

the reception device further includes a processing unit that processesthe received container.

(13) The reception device according to (12), wherein

hierarchical information is inserted into a layer of the container, and

the processing unit retrieves selectively from the video stream theencoded image data of the pictures at a predetermined level and lowerones and decodes the same, based on the hierarchical information, toobtain the image data of the pictures at the predetermined level andlower ones.

(14) A reception method including a reception step by a reception unitof receiving a container in a predetermined format containing a videostream that has encoded image data of pictures at a plurality of levelsobtained by classifying image data of the pictures constituting movingimage data into the respective levels and encoding the same,

in the encoding, hierarchical composition is equalized between alow-level side and a high-level side, and corresponding pictures on thelow-level side and the high-level side are combined into one set and aresequentially encoded, and

the reception method further includes a processing step of processingthe received container.

INDUSTRIAL APPLICABILITY

A main feature of the subject technique is in that the hierarchicalcomposition is equalized between the low-level side and the high-levelside, and corresponding pictures on the low-level side and thehigh-level side are combined into one set and are sequentially encoded,thereby allowing the reception side to decode the encoded image data ofthe pictures on the low-level side and the high-level side with asmaller buffer size and a reduced decoding delay (see FIGS. 3 and 5 ).Another main feature of the subject technique is in that thehierarchical information is inserted into the layer of the container toallow the reception side to retrieve selectively from the video streamthe encoded image data of the pictures up to the level commensurate withthe capability of the decoder in an easy manner (see FIGS. 7A and 7B,and FIGS. 11 to 16 ).

REFERENCE SIGNS LIST

-   10 Transmission/reception system-   100 Transmission device-   101 CPU-   102 Encoder-   103 Compressed data buffer (cpb)-   104 Multiplexer-   105 Transmission unit-   200 Reception device-   201 CPU-   202 Reception unit-   203 Demultiplexer-   204 Compressed data buffer (cpb)-   205 Decoder-   206 Decompressed data buffer (dpb)-   207 Post-processing unit-   208 Display unit

1. (canceled)
 2. A reception device comprising: circuitry configured toreceive a container including a video stream having encoded image dataon a low-level side and a high-level side generated by performinghierarchical encoding on image data of pictures constituting movingimage data, and a table describing one or more video streams included inthe container, the table including hierarchical information including alevel specified value of the encoded image data on the low-level sideand a level specified value of the video stream, wherein the levelspecified value of the encoded image data on the low-level side and thelevel specified value of the video stream are inserted into a layer ofthe video stream; decode the encoded image data on the low-level side orthe encoded image data on both the low-level side and the high-levelside included in the received container to obtain the image data of thepictures constituting the moving image data; and subject the obtainedimage data to interpolation to increase the frame rate of the obtainedimage data according to a display capability.
 3. The reception deviceaccording to claim 2, wherein the circuitry is configured to subject theobtained image data to interpolation to increase the frame rate of theobtained image data in response to a determination that the obtainedimage data corresponds to a frame rate smaller than a frame ratecorresponding to the display capability.
 4. The reception deviceaccording to claim 2, wherein the circuitry is configured to match theframe rate of the obtained image data with the display capability by theinterpolation.
 5. The reception device according to claim 2, wherein thecircuitry is configured to decode the encoded image data on thelow-level side or the encoded image data on both the low-level side andthe high-level side included in the received container depending on adecoding capability to obtain the image data of the picturesconstituting the moving image data.
 6. The reception device according toclaim 5, wherein the circuitry is configured to decode the encoded imagedata on the low-level side or the encoded image data on both thelow-level side and the high-level side from the video stream dependingon the decoding capability according to at least one of the levelspecified value of the encoded image data on the low-level side or thelevel specified value of the video stream.
 7. The reception deviceaccording to claim 5, wherein the circuitry is configured to retrievethe encoded image data on the low-level side or the encoded image dataon both the low-level side and the high-level side from the video streamdepending on the decoding capability based on the hierarchicalinformation.
 8. The reception device according to claim 5, wherein thecircuitry is configured to match the frame rate of the obtained imagedata with the display capability by the interpolation.
 9. The receptiondevice according to claim 3, wherein the circuitry is further configuredto subject the obtained image data to sub sampling to decrease the framerate of the obtained image data in response to a determination that theobtained image data corresponds to a frame rate larger than the framerate corresponding to the display capability.
 10. The reception deviceaccording to claim 2, wherein the container is in MPEG-4 Part 14 (MP4)format.
 11. The reception device according to claim 2, wherein thecircuitry is configured to display the obtained image data in theincreased frame rate.
 12. The reception device according to claim 11,further comprising a display configured to display the obtained imagedata.
 13. The reception device according to claim 12, wherein thedisplay is a liquid crystal display (LCD) or an organicelectro-luminescence (EL) display.
 14. The reception device according toclaim 2, wherein the circuitry is configured to output the obtainedimage data to an external device to display in the increased frame rate.15. A reception method comprising: receiving a container including avideo stream having encoded image data on a low-level side and ahigh-level side generated by performing hierarchical encoding on imagedata of pictures constituting moving image data, and a table describingone or more video streams included in the container, the table includinghierarchical information including a level specified value of theencoded image data on the low-level side and a level specified value ofthe video stream, wherein the level specified value of the encoded imagedata on the low-level side and the level specified value of the videostream are inserted into a layer of the video stream; decoding theencoded image data on the low-level side or the encoded image data onboth the low-level side and the high-level side included in the receivedcontainer to obtain the image data of the pictures constituting themoving image data; and subjecting the obtained image data, in responseto a determination that the obtained image data corresponds to a framerate smaller than a frame rate corresponding to a display capability, tointerpolation to increase the frame rate of the obtained image data. 16.The reception method according to claim 15, further comprisingsubjecting the obtained image data to interpolation to increase theframe rate of the obtained image data in response to a determinationthat the obtained image data corresponds to a frame rate smaller than aframe rate corresponding to the display capability.
 17. The receptionmethod according to claim 15, further comprising matching the frame rateof the obtained image data with the display capability by theinterpolation.
 18. The reception method according to claim 15, furthercomprising decoding the encoded image data on the low-level side or theencoded image data on both the low-level side and the high-level sideincluded in the received container depending on a decoding capability toobtain the image data of the pictures constituting the moving imagedata.
 19. The reception method according to claim 18, further comprisingdecoding the encoded image data on the low-level side or the encodedimage data on both the low-level side and the high-level side from thevideo stream depending on the decoding capability according to at leastone of the level specified value of the encoded image data on thelow-level side or the level specified value of the video stream.
 20. Thereception method according to claim 18, further comprising retrievingthe encoded image data on the low-level side or the encoded image dataon both the low-level side and the high-level side from the video streamdepending on the decoding capability based on the hierarchicalinformation.
 21. The reception method according to claim 18, furthercomprising matching the frame rate of the obtained image data with thedisplay capability by the interpolation.